Bag and valve for advanced respiratory support

ABSTRACT

A respiratory device for providing respiratory support to a patient includes an expandable bag and a rigid valve housing portion. The expandable bag includes an air intake valve, an adjustable predetermined tidal volume and a hinge configured to maintain the expandable bag in a predetermined tidal volume in an uncompressed configuration. The rigid valve housing portion in fluid communication with the expandable bag, the valve housing portion includes a peak inspiratory pressure (PIP) mechanism, an adjustable dial configured to adjust both the tidal volume of the expandable bag and a value of the PIP mechanism, a two-way valve configured to allow air to move from the expandable bag in a first direction through a first portion and directs air in an opposing direction through a second portion to create positive end-expiratory pressure (PEEP), and a PEEP controller comprising a PEEP dial configured to select a predetermined PEEP value provided by the two-way valve. The valve housing portion is capable of connecting to a patient breathing interface.

PRIORITY CLAIM

The present application is a continuation-in-part of U.S. patent application Ser. No. 16/687,269, filed on Nov. 18, 2019, which claims priority to U.S. Provisional Patent Application No. 62/843,140, filed on May 3, 2019, the entire disclosures of which are hereby expressly incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates generally to a bag-valve-mask or resuscitator used to ventilate patients in a field setting.

BACKGROUND

A manual resuscitator, or a bag-valve-mask (BVM), is a device used to temporarily push air into the lungs of a patient who is unconscious or otherwise unable to breathe on their own. These devices are found in hospitals and in ambulances throughout the country and in most developed parts of the world.

BVMs have existed for many years. Numerous modifications and enhancements have been made to BVMs over the years, these include enhanced 2-way valves, the addition of a high-pressure relieving “pop-off” valve, and the attachment of an oxygen reservoir to the bag to increase the percent of oxygen content of air flowing into the self-inflating bag portion of the device.

Self-inflating or self-expanding bags are bulky. They typically hold over a liter of air (in an adult model) even when not in use. Two-way valves are also bulky, and make use of a rigid plastic construct that is most commonly shaped in a 90-degree angle. The mask is similarly bulky and typically employs a rigid plastic triangular-shaped device with a soft rubber balloon about a perimeter that interfaces with and forms a seal around the mouth and nose of a victim. Each of these components is bulky in its own right and together, these form a device that is too large and obtuse to be carried in public by individuals who are trained to use them. Thus, when an emergency arises in most non-clinical settings, a BVM is not typically available until after an ambulance has arrived.

Efforts have been made in the past to reduce the overall space occupied by these devices. This includes an entirely collapsible bag with a flexible hollow body that can be stowed into a container. In attempts to make the device smaller, thinner materials have been used. This results in bag-valve-masks that are suitable for one-time use, due to the device losing functionality after its use. Therefore, BVMs are typically only available in a hospital setting or similar clinical location.

In addition to their bulk, traditional BVMs are prone to cause hyperventilation. A condition in which a patient is given too much air. This can result in death. Traditional BVMs cause hyperventilation because they inflate too rapidly, leading lifesavers to give breaths more frequently than is recommended.

Finally, traditional BVMs are only capable of delivering a fixed tidal volume with or without a fixed pressure relief point depending on the size of the BVM (adult, pediatric, or neonatal).

SUMMARY

In general terms, this disclosure is directed towards a respiratory device having an expandable bag and a connection member. The respiratory device allows a user to provide respiratory support to a patient.

In an example embodiment, a respiratory device is described. A respiratory device for providing respiratory support to a patient includes an expandable bag and a rigid valve housing portion. The expandable bag includes an air intake valve, an adjustable predetermined tidal volume and a hinge configured to maintain the expandable bag in a predetermined tidal volume in an uncompressed configuration. The rigid valve housing portion in fluid communication with the expandable bag, the valve housing portion includes a peak inspiratory pressure (PIP) mechanism, an adjustable dial configured to adjust both the tidal volume of the expandable bag and a value of the PIP mechanism, a two-way valve configured to allow air to move from the expandable bag in a first direction through a first portion and directs air in an opposing direction through a second portion to create positive end-expiratory pressure (PEEP), and a PEEP controller comprising a PEEP dial configured to select a predetermined PEEP value provided by the two-way valve. The valve housing portion is capable of connecting to a patient breathing interface.

In a further aspect, a method of providing respiratory support to a patient is described. The method includes providing a respiratory device for providing respiratory support to the patient. The respiratory device includes an expandable bag comprising an air intake valve, the expandable bag having an adjustable predetermined tidal volume and a hinge, the hinge configured to maintain the expandable bag in a predetermined tidal volume in an uncompressed configuration; a rigid valve housing portion in fluid communication with the expandable bag. The valve housing portion includes a peak inspiratory pressure (PIP) mechanism, an adjustable dial configured to adjust both the tidal volume of the expandable bag and a value of the PIP mechanism, a PEEP controller comprising a PEEP dial configured to select a predetermined PEEP value provided by the two-way valve; and an intake mechanism comprising a plurality of adjustable apertures in fluid communication with the expandable bag, an ambient air intake valve, an oxygen intake valve, and an exhaust valve. The patient breathing interface in fluid communication with the rigid valve housing portion. The method further includes selecting a predetermined value of the tidal volume and the value of the PIP valve on the adjustable dial and selecting a PEEP value on the PEEP controller. The respiratory device is configured for single-handed use by a user.

In another aspect, a respiratory device for providing respiratory support to a patient is described. The respiratory device includes an expandable bag, an adjustable intake mechanism, and a rigid valve housing portion. The expandable bag includes an air intake valve, and having an adjustable predetermined tidal volume and a hinge, the hinge configured to maintain the expandable bag in a predetermined tidal volume in an uncompressed configuration. The adjustable intake mechanism in fluid communication with the expandable bag, and includes an ambient air intake valve, an oxygen intake valve, and an exhaust valve. The rigid valve housing portion is in fluid communication with the expandable bag, and includes a peak inspiratory pressure (PIP) mechanism, an adjustable dial configured to adjust both the tidal volume of the expandable bag and a value of the PIP mechanism, a two-way valve configured to allow air to move from the expandable bag in a first direction and directs air through a positive end-expiratory pressure (PEEP) valve in an opposing direction, and a PEEP controller comprising a PEEP dial and a lifting piece, wherein movement of the PEEP dial lifts the lifting piece relative to the two-way valve to adjust a distance between the lifting piece and the two-way valve, to select a predetermined PEEP value provided by the two-way valve. The valve housing portion is capable of connecting to a patient breathing interface.

In yet another aspect, a rigid valve housing portion for use in providing respiratory support to a patient is described. The valve housing portion includes a peak inspiratory pressure (PIP) mechanism, an adjustable dial configured to adjust both a tidal volume of an expandable bag and a value of the PIP mechanism, a two-way valve configured to allow air to move from the expandable bag in a first direction through a first portion and directs air in an opposing direction through a second portion to create positive end-expiratory pressure (PEEP), and a PEEP controller comprising a PEEP dial configured to select a predetermined PEEP value provided by the two-way valve. The valve housing portion is capable of connecting to a patient breathing interface.

Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate an embodiment of the invention, and such exemplifications are not to be construed as limiting the scope of the invention in any manner.

BRIEF DESCRIPTION OF THE DRAWINGS

The inventive aspects of the present disclosure can be more easily understood, and further advantages and uses thereof can be more readily apparent, when considered in view of the detailed description and the following figures in which:

FIG. 1 illustrates an example embodiment of an expandable bag having features that are examples of inventive aspects in accordance with the present disclosure.

FIG. 2 illustrates a perspective view of the back side of the expandable bag of FIG. 1.

FIG. 3 illustrates a first side view of the expandable bag.

FIG. 4 illustrates a second side view of the expandable bag.

FIG. 5 illustrates a vertical cross-sectional view of the expandable bag of FIG. 1.

FIG. 6 illustrates a third side view of the expandable bag.

FIG. 7 illustrates a fourth side view of the expandable bag.

FIG. 8 illustrates a top view of the expandable bag.

FIG. 9 illustrates a bottom view of the expandable bag.

FIG. 10 illustrates a horizontal cross-sectional view of the expandable bag.

FIG. 11 illustrates a top view of the expandable bag in an expanded configuration.

FIG. 12 illustrates a bottom view of the expandable bag in an expanded configuration.

FIG. 13 illustrates a cross-sectional view of the two-way valve portion.

FIG. 14 illustrates a cross-sectional view of another embodiment of the two-way valve portion.

FIG. 15 illustrates a cross-sectional view of another embodiment of the two-way valve portion.

FIG. 16 illustrates a cross-sectional view of another embodiment of the two-way valve portion.

FIG. 17 illustrates a top cross-section view of the barrel-valve embodiment of the integrated PEEP valve.

FIG. 18 illustrates a perspective view of an over breathing valve.

FIG. 19 illustrates an alternative view of a groove and track embodiment of an integrated PEEP valve.

FIG. 20 illustrates an alternative embodiment of a PEEP controller.

FIG. 21 shows the expandable bag device including an expandable bag.

FIG. 22 illustrates a rear view of the expandable bag device.

FIG. 23 illustrates an example embodiment of the valve housing member.

FIG. 24 illustrates a top view of the expandable bag device in an expanded configuration.

FIG. 25 illustrates an alternative side view of the expandable bag device.

FIG. 26 shows another side view of the expandable bag device.

FIG. 27 illustrates a bottom view of the expandable bag in an expanded configuration.

FIG. 28 shows another view of the expandable bag device.

FIG. 29 illustrates an isolated view of the valve housing member.

FIG. 30 illustrates a cutaway view of the valve housing member.

FIG. 31 illustrates a view of the valve housing member highlighting the PIP override tab.

FIG. 32 illustrates a cutaway view of the valve housing member.

FIG. 33 illustrates a partial cutaway view of the valve housing member.

FIG. 34 shows the location of the PIP override tab when viewed through the valve housing member.

FIG. 35 illustrates an exploded view of the valve housing member.

FIG. 36 shows the expandable bag device with the expandable bag in an expanded configuration.

FIG. 37 illustrates a cutout side view of the air intake mechanism.

FIG. 38 illustrates a top view of the expandable bag device in a compressed configuration.

FIG. 39 illustrates a partial cutaway view of the valve housing member.

FIG. 40 illustrates an exploded view of the air intake mechanism.

FIG. 41 illustrates a bottom view of the valve connection member.

FIG. 42 illustrates a view of the expandable bag in an expanded configuration.

FIG. 43 illustrates an embodiment of the air intake mechanism with the slide in a first position.

FIG. 44 illustrates an embodiment of the air intake mechanism with the slide in a second position.

FIG. 45 illustrates an embodiment of the air intake mechanism with the slide in a third position.

DETAILED DESCRIPTION

The figures and descriptions provided herein may have been simplified to illustrate aspects that are relevant for a clear understanding of the herein described devices, systems, and methods, while eliminating, for the purpose of clarity, other aspects that may be found in typical devices, systems, and methods. Those of ordinary skill may recognize that other elements and/or operations may be desirable and/or necessary to implement the devices, systems, and methods described herein. Because such elements and operations are well known in the art, and because they do not facilitate a better understanding of the present disclosure, a discussion of such elements and operations may not be provided herein. However, the present disclosure is deemed to inherently include all such elements, variations, and modifications to the described aspects that would be known to those of ordinary skill in the art.

References in the specification to “one embodiment,” “an embodiment,” “an illustrative embodiment,” etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may or may not necessarily include that particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to affect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described. Additionally, it should be appreciated that items included in a list in the form of “at least one A, B, and C” can mean (A); (B); (C); (A and B); (A and C); (B and C); or (A, B, and C). Similarly, items listed in the form of “at least one of A, B, or C” can mean (A); (B); (C); (A and B); (A and C); (B and C); or (A, B, and C).

In the drawings, some structural or method features may be shown in specific arrangements and/or orderings. However, it should be appreciated that such specific arrangements and/or orderings may not be required. Rather, in some embodiments, such features may be arranged in a different manner and/or order than shown in the illustrative figures. Additionally, the inclusion of a structural or method feature in a particular figure is not meant to imply that such feature is required in all embodiments and, in some embodiments, may not be included or may be combined with other features.

Generally, bag-valve-masks (BVM) are comprised of three key components: a self-inflating bag, a two-way valve, and a mask. The bag is designed to expand, fill and retain a volume of air. This volume constitutes the next “breath” that a patient is to receive. When the bag is compressed by a lifesaver's hand (herein referred to as the user), the breath is pushed through a valve and down into the mask portion of the device. The mask is kept in contact with the patient's face and directs the breath downward and into the mouth or nasal passage of the patient and into their lungs. When the bag compression is released, the bag expands and a new volume of “fresh” air is drawn into the bag while the original breath of “used” air exits the patient and is released into the ambient air via the two-way valve.

The disclosure is directed generally to a BVM device having an expandable bag and a connection member in fluid communication with the expandable bag. More specifically, the respiratory device is able to provide different tidal volumes and different PEEP values to a patient.

FIG. 1 illustrates an example embodiment of an expandable bag device 100. The expandable bag device 100 includes an expandable bag portion 102 and connection member 150. The expandable bag device 100 may be attached to any type and size of mask or other patient breathing interface device, such as an endotracheal tube or laryngeal mask airway. The expandable bag portion 102 includes an expandable bag 104, a first side panel 106 a, second side panel (not shown), a first handle portion 108 a, a second handle portion (not shown), and at least one air intake valve 110.

In an example embodiment, the expandable bag 104 has an accordion-like design, comprising a plurality of folds 114 a, 114 b, such as a bellow, or other similar mechanism. The plurality of folds 114 allows the expandable bag 104 to expand and contract. This allows the expandable bag 104 is occupy minimal space when not in use. The expandable bag 104 can be made from a variety of materials such as flexible plastics. The expandable bag 104 includes a side panel 106 that is stiffer than the expandable bag 104 to allow a user to hold the side panel 106 a to compress the expandable bag 104. The side panel 106 a is made from a plastic that has a rigidity greater than the expandable bag 104. The side panel 106 a also comprises a handle portion 108 a. The handle portion 108 a may optionally be raised or depressed from the side panel 106 a to provide a surface for a user's fingers to grip and/or grab when compressing the expandable bag 104.

The rigidity of the side panel 106 a allows a user to press against it in order to compress the expandable bag 104. This allows a user to compress the expandable bag portion 102 fully, as when a user compresses the side panels 106 a, the side panel 106 a compresses the entire length of the expandable bag 104.

The side panels 106 may also be configured to be easily held in a user's hand. In an example, the side panels 106 may each include an angled plate that makes it easier for the user to hold in one hand while inflating and deflating the bag even if the user's grip is relaxed on the expandable bag 104. Additionally or alternatively, the side panels 106 may include a grip material, such as rubber that makes it easily to hold. In yet another embodiment, the side panels 106 include a recess or legs that a user can grip with their hand. In yet another embodiment the side panels 106 could include a strap (not shown) to help the user maintain contact with the sides of the device.

The first side panel 106 a and expandable bag 104 also include a first air intake valve 110 a. The first air intake valve 110 a extends through the first side panel 106 a and into the expandable bag 104. The first air intake valve 110 a provides the expandable bag 104 with ambient air intake to re-inflate the expandable bag 104. In an embodiment, each side panel 106 may comprise an air intake valve 110. In an alternative embodiment, the first side panel 106 a includes the first air intake valve 110 a.

The expandable bag 104 is a self-inflating bag, in which the expandable bag 104 takes on an expanded configuration without any external input from the environment. The interior of the expandable bag 104 includes a spring, which is described in more detail below.

The expandable bag portion 102 is connected to a connection member 150. The connection member 150 includes a pressure relief valve 154 located at the top 152 of the connection member 150, a dial 158, and a mask connection member 162. In an embodiment, the pressure relief valve 154 is a one-way valve that only lets air flow from inside the connection member 150 to the external environment.

The dial 158 controls the positive end expiratory pressure (PEEP) valve, which is the controlled resistance of the exhaled airflow. The dial 158 controls the location of side panels of an internal valve, such as a barrel valve (shown in FIGS. 13-17). When the dial 158 is turned up, the side panels move closer together, so it is harder for the patient to exhale against. The dial 158 can have different values such as from 0 to 20 mmHg. Alternatively, a push button (shown in FIG. 20) may be used to control PEEP.

The connection member 150 also includes two optional external pressure gauge connection members 156, 160. The optional external pressure gauge connection members 156, 160 can be used to indicate the internal pressure levels of different components of the expandable bag device 100. The external pressure gauge connection member 156, 160 can be used to measure the pressure of a patient's lungs upon inspiration (PIP—peak inspiratory pressure). The external pressure gauge connection member 156, 160 can be used to measure the pressure of the patient's lungs during exhalation (PEEP). In other embodiments, these two valves are not present, or are capable of being closed.

The connection member 150 is made from a stiff material that allows a user to hold the expandable bag device 100 in one hand. A user is able to compress the expandable bag portion 102 with one hand, while maintaining a seal of a mask on a patient's face with the same hand. The stiffness of the connection member 150 allows for single-handed use of the expandable bag device 100.

FIG. 2 illustrates a rear view of the expandable bag device 100. As shown, the expandable bag portion 102 includes a second side panel 106 b having a second handle portion 108 b, and a second air intake valve 110 b. The second side panel 106 b having a second handle portion 108 b and the second air intake valve 110 b are the same as the first side panel 106 a, the first handle portion 108 a, and the first air intake valve 110 a shown in FIG. 1, and the descriptions of which are omitted for the sake of brevity. The first side panel 106 a and the second side panel 106 b sandwich the expandable bag 104.

A plurality of attachment points 116 are located along each side panel 106 to attach each side panel 106 to the expandable bag 104. Various types of attachment mechanisms may be used to attach each side panel 106 to the expandable bag 104, such as adhesives or mechanical connections.

Still referring to FIG. 2, the expandable bag 104 is attached to the connection member 150 via the bag connection member 120. The connection member 150 may be fixedly connected to the expandable bag portion 102, or alternatively, may be removable. In a removable embodiment, an attachment mechanism may be selected from a snap fit, friction fit, or other similar mechanism.

In an example embodiment, the connection member 150 includes an “over-breathing” valve (not shown). As shown in more detail at FIG. 17, the over-breathing valve allows a patient to breathe on their own, even without the expandable bag 104 providing the air. For example, if a patient has a mask on, and the patient can or begins to breathe on their own, the over-breathing valve allows the patient to breathe.

The expandable bag device 100 is shaped such that it takes up minimal space during storage. When the expandable bag device 100 is not being used, a mask (not shown) is detachable from the mask connection member 162, and can be stored next to the expandable bag portion 102. In order to take up minimal space, the expandable bag portion 102 has a shape that allows the mask portion to abut against it, such as having the expandable bag portion 102 having a rounded concave shape. Still further, the expandable bag device 100 is designed so the expandable bag portion 102 is compressible and does not hold any air when not in use.

The expandable bag device 100 is configured to be used by a user to provide respiratory support to a patient. In use, the expandable bag device 100 is connected to a mask (not shown) at the mask connection member 162, which provides air to a patient in need. The expandable bag device 100 is biasable at the articulation point 112, by a user. The articulation point 112 maintains the expandable bag 104 in an open or expanded configuration (shown in more detail below at FIGS. 11-12). When a user compresses the side panels 106 a, 106 b, the expandable bag 104 compresses, which forces air through the bag connection member 120 (discussed in more detail below), through the connection member 150 and into a mask (not shown). Alternatively, the connection member 150 may be connected to a different patient breathing interface, such as an endotracheal tube, an end-tidal CO₂ connector, or a laryngeal mask airway.

In an embodiment, the articulation point 112 is a spring located within the expandable bag 104. The articulation point 112 may be made from a material such as metal, fiberglass, carbon fiber, plastic, or any other structural material that will bias the expandable bag 104 in an inflated or expanded configuration. The articulation point 112 has a strength great enough to keep the bag open when not subject to external forces, but weak enough that a user can squeeze the side panels 106, which bias the articulation point 112 with one hand. Still further, the articulation point 112 is designed with a material that does not allow the expandable bag 104 to open too quickly. For example, the articulation point 112 comprises a hinge that is configured to inflate the expandable bag 104 in 5-6 seconds; however, other time periods may be utilized.

The expandable bag device 100 is configured such that when a user compresses the side panels 106 a, 106 b, the entire expandable bag 104 is compressed. This allows the expandable bag 104 to have a size that is the volume of air needed, without having to be oversized. This also allows the expandable bag 104 to be as compact as possible.

When a user desires to provide subsequent “breaths,” the user relaxes the compression on the side panels 106 a, 106 b of the expandable bag 104, which allows the expandable bag 104 to expand into the expanded configuration. The air intake valves 110 allows air to move from an external environment to the inside of the expandable bag 104.

In another embodiment, the expandable bag portion 102 further comprises an oxygen port 121 which can be connected to a source of oxygen (not shown). In use, an oxygen port 121 can instill a predetermined volume of pure oxygen in the expandable bag portion 102. When the expandable bag portion 102 is expanded, it can pull in ambient air from the periphery to blend with the oxygen from an oxygen source which is coupled to the expandable bag portion 102 by the oxygen port 121.

The oxygen port 121 may further include an indicator (not shown) that indicates to the user that oxygen is flowing into the expandable bag 104. An example indicator may be a flap, a spinner, or a valve that moves due to the flow of oxygen, and the user is able to see the movement of the indicator. In such an example, the indicator may be translucent and the indicator may be colored. In another example, the indicator may have a noise-making device that whistles when oxygen is flowing through the indicator into the expandable bag 104.

FIG. 3 illustrates a side view of the expandable bag device 100. The bag connection member 120 connects the expandable bag portion 102 to the connection member 150. The bag connection member 120 includes a lumen, and may or may not include a valve. In an embodiment comprising a valve, the valve is a one-way valve that only allows air to move from the expandable bag portion 102 to the connection member 150.

In an example embodiment, the expandable bag portion 102 also includes a buckle 302. The buckle 302 allows a strap (not shown) to be connected to a first side panel 106 a and a second side panel 106 b. The length of the strap can determine how much the expandable bag 104 can expand. For example, a strap with a first length connected to each of the buckles 302 restricts the expandable bag 104 from opening more than a first predetermined fill volume. A strap with a second length can restrict the expandable bag 104 from opening more than a second predetermined fill volume. This allows the expandable bag device 100 to be used on patients with different sizes of lungs. For example, a short strap may be required for a neonatal patient and a long strap for a pediatric patient. No strap may be required for an adult patient.

In an alternative embodiment, a single strap may include multiple buckles at predetermined lengths, so a single strap may be used for different predetermined fill volumes. The strap can include indicia that indicates which buckle is to be used with each type of patient.

The straps (not shown) may include indicia on each that conveys pertinent information for the resuscitation of each patient size. For example, the shorter strap for older pediatric patients might remind a user to give 15 compressions for 2 rescue breaths when cardiopulmonary resuscitation is given by the user.

In yet another embodiment, a dial or push button mechanism 303 may be used to control the tidal volume. The push button mechanism 303 controls how large the expandable bag portion 102 is able to expand. For example, the push button mechanism 303 may include three different pre-determined volumes, such as a tidal volume for a neonatal patient, a second tidal volume for a pediatric patient, and a third tidal volume for an adult patient. This allows the expandable bag device 100 to be used on patients with different sizes of lungs.

FIG. 4 illustrates an opposing side view of the expandable bag device 100. In an example embodiment, the connection member 150 includes a first external pressure gauge connection member 156 and a second external pressure gauge connection member 160. As described above, these external pressure gauge connection members 156, 160 allow a user to attach a pressure gauge to determine the pressure provided or received at each of the external pressure gauge connection members 156, 160. The opposing side also includes a buckle 302, the details of which are omitted for brevity.

In an embodiment, the pressure relief valve 154 includes a dial 155 that allows the pressure at which the pressure relief valve 154 vents air to be adjustable. In an embodiment, the pressure relief valve 154 is configured to vent air at a pressure of 40 cm water. In another embodiment, the pressure at which the pressure relief valve 154 vents air is adjustable. An adjustable pressure relief valve 154 may be controllable the dial 155 or other similar mechanism.

FIG. 5 illustrates a vertical cross-sectional view of the expandable bag device 100. The connection member 150 includes the pressure relief valve 154 located at the top of the connection member 150, a PEEP valve 501, and a two-way valve a located above a mask connection lumen 506. The two-way valve 504 may be a duckbilled valve.

The pressure relief valve 154 may be a ball-and-spring valve that relieves excess pressure. Alternatively, the pressure relief valve 154 may be a pop-off valve, a stiffened duck-billed or other type of valve. The pressure relief valve 154 is a one-way valve, so air only moves from the inside of the connection member 150 to the external environment.

The PEEP valve 501 may be comprises of two separate valves, each located lateral to the two-way valve 504. In an example embodiment, the PEEP valve 501 includes two barrel valves 502. For example, a first side of the barrel valve 502 a is located on a first side of the two-way valve 504 and a second side of the barrel valve 502 b is located on a second side of the two-way valve 504. This is shown in more detail at FIGS. 13-16. As described above, the PEEP valve 501 is controlled by the dial 158.

The two-way valve 504 allows air to move from the connection member 150 through the mask connection lumen 506 into a mask (not shown) for a patient to breathe. This is shown in more detail at FIGS. 13-16.

In an alternative embodiment, the PEEP valve 501 may be a different type of valve, such as a torsion valve or a compression valve. Other types of valves include duckbill, diaphragm, spool, butterfly, needle, ball, gate, poppet, plug, and flapper.

The expandable bag device 100 is biasable at the articulation point 112. The expandable bag portion 102 includes a biasing member 512 connected to front side and back side of the expandable bag 104 at connection point 510. The biasing member 512 may be a spring, or other type of member that allows the bag to articulate at the articulation point 112. The biasing member 512 has a strength such that it does not cause the expandable bag 104 to open too quickly when in use. Other types of biasing members include but are not limited to torsion, compression, extension, bow, leaf, conical, flat, and disk/cup members.

Also shown is the air intake valve 110 of the expandable bag 104. The air intake valve 110 allows air from the external environment to fill the expandable bag 104. The air intake valve 110 may further include an indicator (not shown) that indicates to the user that the expandable bag 104 is inflating and when the expandable bag 104 has completed inflating. An example indicator may have a noise-making device that whistles when the expandable bag 104 is inflating and stops making noise when the expandable bag 104 is full. For example, the indicator may be made from a flexible material, such as a thin plastic or thin rubber.

FIG. 6 illustrates a view of the connection member 150 with the expandable bag portion 102 located behind it. As shown, the expandable bag 104 of the expandable bag portion 102 is compressed. In a compressed configuration, the expandable bag 104 has a width of a first end that is the same as a width of an opposing end. For example, the width w₁ of the expandable bag portion 102 may be from about 2 cm to about 15 cm.

FIG. 7 illustrates another view of the expandable bag portion 102 in a compressed configuration. In an embodiment, a second width w₂ of the expandable bag portion 102 may be from about 4 cm to about 30 cm.

FIG. 8 illustrates a top view of the expandable bag device 100. The expandable bag 104 has an accordion-type shape including a plurality of folds 114 a, 114 b. The plurality of folds 114 enables the expandable bag 104 to expand to a maximum capacity. A maximum capacity may be one fluid liter. In alternative embodiments, the maximum capacity may be more, such as 1.5 fluid leaders, or less, such as 0.5 fluid leaders. The length l of the expandable bag portion 102 may be from about 5 cm to about 50 cm.

The expandable bag 104 includes the articulation point 112 at an end connected to the connection member 150. The opposing end of the expandable bag 104 expands when articulation point 112 is in a biased configuration.

The top portion of the connection member 150 comprises the pressure relief valve 154. As discussed above, the pressure relief valve 154 allows air to flow from the connection member 150 to the external environment in the event that excessive pressures are applied to a patient's lungs.

FIG. 9 illustrates a bottom view of the expandable bag device 100. The connection member 150 includes the mask connection lumen 506, which allows the connection member 150 to connect to a mask or other patient breathing interface unit (not shown).

FIG. 10 illustrates a horizontal cross-sectional view of the expandable bag device 100. Articulation point 112 is located at a first end of the expandable bag portion 102. The articulation point 112 is configured to maintain an open expanded configuration, until at which time pressure is applied externally to the expandable bag portion 102 to collapse the expandable bag 104 by a user. The biasing member 512 is connected to front side 1002 and back side 1004 of the expandable bag 104 at connection point 510 a, 510 b. The biasing member 512 may be a spring, or other type of member that allows the bag to articulate at the articulation point 112. Other types of biasing members include but are not limited to torsion, compression, extension, bow, leaf, conical, flat, and disk/cup members.

FIG. 11 illustrates a top view of the expandable bag device 100 in an expanded configuration. As shown, the expandable bag portion 102 has a generally triangular-shape when in an expanded configuration. The bag could assume other shapes such as spherical, ovoid, square, rectangular, or other polygonal shape. The end 1102 of the expandable bag portion 102 opposite the connection member 150 is expanded, allowing the expandable bag 104 to fill with air. The biasing member (not shown) opens the expandable bag to a predetermined fluid volume.

FIG. 12 illustrates the expandable bag device 100 from a bottom viewpoint, in an expanded configuration. The connection member 150 includes a mask connection member 162 and the two-way valve 504 located within the mask connection lumen 506.

FIGS. 13-16 illustrate a cross-sectional view of the connection member 150. In particular, FIG. 13 shows the connection member 150 that includes the two-way valve 504 located centrally in the mask connection lumen 506. The two-way valve 504 includes two flaps that meet each other in a center of the mask connection lumen 506. The connection member 150 also includes the PEEP valve 501, which includes at least one barrel valve 502 located laterally to the two-way valve 504. For example, a first barrel valve 502 a is located on a first side of the two-way valve 504, and a second barrel valve 502 b is located on an opposing side of the duckbilled valve.

The PEEP valve 501 is controlled by a dial (not shown) and can be adjusted to a predetermined expiratory pressure amount. The PEEP valve 501 maintains the predetermined pressure in the lungs of the patient. The two-way valve 504 allow air from the expandable bag 104 to be provided to the patient and forces exhaled air to be expelled through the PEEP valve 501.

FIG. 14 illustrates an alternative embodiment of a two-way valve 504. For example the duckbilled valve includes only a single flap, where the single flap meets a side edge of the valve.

FIGS. 15-16 also illustrate an alternative embodiment of a two-way valve 504 and a groove mechanism 1502 of a dial 158. The two-way valve 504 includes two flaps that meet in a middle portion, wherein the flaps have a small articulation before joining together.

FIG. 17 illustrates a top down cutaway view of the two-way valve 504 and the barrel valves 502 a, 502 b. The dial 158 controls the size of the barrel valves 502 a, 502 b. A user can rotate the dial 158 in a first direction to increase the size of the barrel valves 502, and can rotate the dial 158 in an opposing direction to decrease the size of the barrel valves 502.

The dial 158 is used to adjust the relative positions of cutouts 1702, 1704. When the dial 158 is turned fully in one direction, for example when fully turned clockwise, the cutouts 1702, 1704 do not overlap, which restricts the flow of exhaled air from the patient into the periphery. When the dial 158 is turned fully in the other direction, for example fully counterclockwise, the cutouts 1702, 1704 overlap, allowing exhaled air to readily vent into the periphery through the holes 1710, 1712 of the barrel valve 502 b, 502 b. The dial 158 can be set to an infinite number of positions between fully open, counterclockwise, and fully closed, clockwise allowing for infinite adjustments of PEEP.

FIG. 18 illustrates an example expandable bag device 100 having an over breathing valve 1802 on the connection member 150. The over breathing valve 1802 is a one-way valve that allows a patient to inhale on their own, without the use of the air provided by the expandable bag portion 102. The over breathing valve 1802 may be a diaphragm valve, or any other type of one-way valve commonly known in the art. Exhalation from the patient, or positive pressure from the expandable bag portion 102, would effectively close over breathing valve 1802 during operation.

Inside the over breathing valve 1802 may be an additional valve unit (not shown). The additional valve unit may be duck billed in shape or other potential embodiments. This valve allows the patient to inspire air from the periphery independent of whether or not the user is compressing the expandable bag portion 102 to deliver air to the patient. When the user compresses the expandable bag portion 102, the over breathing valve 1802 closes to prevent loss of inspiratory air from the bag to the periphery.

FIG. 19 illustrates an alternative embodiment of a PEEP valve 501. The PEEP valve 501 includes a groove and track embodiment and a dial 158. The dial 158 is used to raise a lifting piece 1902 against a duckbilled-type valve. This is done by moving the relative position of lifting piece 1902 within the groove 1904. In this embodiment there are three potential positions of the lifting piece within the groove: a low position 1906, an intermediate position 1910, and a high position 1908. When the lifting piece 1902 is located in the low position 1906, the lifting piece 1902 is in its lower-most and least restrictive position against the duckbilled valve. This allows for ready exhalation from the patient and generates no PEEP. When the lifting piece 1902 is located in the intermediate position 1910, the lifting piece 1902 is lifted slightly against the duckbilled valve. This requires additional exhaled force in order to vent to the periphery and generates low PEEP. When the lifting piece 1902 is located in the high position 1908, the lifting piece 1902 is lifted tightly against the duckbilled valve. This requires substantial exhaled force in order to vent to the periphery and generates high PEEP. Additional positions within the groove 1904 could be added for additional adjustment of PEEP.

FIG. 20 illustrates another embodiment of a PEEP controlling device. A push-button mechanism 159 is used to control the PEEP valve. The push-button mechanism 159 controls the PEEP valve, which is the controlled resistance of the exhaled airflow. The push-button mechanism 159 controls the location of side panels of an internal valve, such as a barrel valve (shown in FIGS. 13-17). When the push-button mechanism 159 is completed pushed to one end, the side panels move closer together, so it is harder for the patient to exhale against. When the push-button mechanism 159 is completed pushed to the alternative end, the side panels move farther apart, so it is easier for the patient to exhale against. The push-button mechanism 159 can have different values such as from 0 to 20 mmHg.

The push-button mechanism 159 may include a plurality of selectable buttons, each selectable button corresponds to a pre-determined value. A user is able to select the button that corresponds to the desired PEEP value.

In an alternative embodiment, the PEEP controlling mechanism, in the form of a push-button mechanism 159, may generate PEEP by applying a plunger (not shown) that applies pressure against the upper aspect of the two-way valve 504. This plunger restricts lifting of the two-way valve 504 resisting exhalation and generating PEEP.

FIGS. 21-44 illustrate an alternative embodiment of an expandable bag device 2000. FIG. 21 shows the expandable bag device 2000 including an expandable bag 2004 located between a first side panel 2002 a and a second side panel 2002 b. The expandable bag device 2000 also includes a valve housing member 2001 extending from a first end of the first and second side panels 2002 a, 2002 b. The valve housing member 2001 may be attached to any type and size of mask or other patient breathing interface device, such as an endotracheal tube or laryngeal mask airway.

The first side panel 2002 a and the expandable bag 2004 also includes an air intake mechanism 2040. The air intake mechanism 2040 includes at least one aperture that extends through the first side panel 2002 a and into the expandable bag 2004. In an alternative embodiment, the air intake mechanism 2040 is located on the second side panel 2002 b, and still further an air intake mechanism 2040 may be located on both the first side panel 2002 a and the second side panel 2002 b. The air intake mechanism 2040 is described in more detail below, for example at FIGS. 37 and 40.

In an example embodiment, the expandable bag 2004 has an accordion-like design, comprising a plurality of folds 2005 a, 2005 b, 2005 c, such as a bellow, or other similar mechanism. The plurality of folds 2005 a, 2005 b, 2005 c allows the expandable bag 2004 to expand and contract while filling with air, but also being able to occupy a minimal amount of space when not in use. The expandable bag device 2000 includes a first side panel 2002 a and a second side panel 2002 b that are stiffer than the expandable bag 2004 to allow a user to hold the side panels 2002 a, 2002 b to compress the expandable bag 2004.

The rigidity of the side panels 2002 a, 2002 b allow a user to compress the expandable bag 2004, and this combined with the rigidity of the valve housing portion 2001 allows a user to compress the expandable bag 2004 fully and with a single hand while also maintaining a seal with a patient breathing interface around a patient's mouth with the same hand. As described in more detail below, the expandable bag device 2000 allows for single-handed use by a user.

The expandable bag 2004 is a self-inflating bag, in which the expandable bag 2004 takes on an expanded configuration without any external input from the environment. The expandable bag device 2001 includes a spring (not shown) that pushes the side panels 2002 a, 2002 b away from each other to increase the volume of the expandable bag 2004. The maximum volume of the expandable bag 2004 is controlled by a tidal volume controller within a control dial 2012, as described in more detail below.

The expandable bag device 2000 includes a valve housing member 2001, which is made from a rigid material. The valve housing member 2001 connects the expandable bag 2004 to a patient breathing interface. The valve housing member 2001 includes a pressure relief opening 2013 capped by a control dial 2012. The valve housing member 2001 also includes at least, a PEEP dial 2010, a port 2008, and a mask connection member 2006.

The pressure relief opening 2013 is located at the top of the valve housing member 2001 and is a one-way valve that only lets air flow from inside the valve housing member 2001 to the external environment when the pressure within the valve housing member 2001 is above a predetermined level. This opening 2013 in alternative embodiments may be moved to another location within the valve housing member.

The control dial 2012 simultaneously controls the tidal volume of the expandable bag 2004 and the peak inspiratory pressures that the patient's lungs will experience. In other words, the control dial 2012 restricts how far the first and second side panels 2002 a, 2002 b of the expandable bag 2004 expand, which determines the volume of air being administered to the patient and the PIP that the patient's lungs will experience. The control dial 2012 includes a plurality of predetermined settings, including for example, large adult, adult, pediatric, and infant. Each of these settings provides an appropriate tidal volume, which is dependent on the size of the patient. As shown in the figure, an indicia, such as “LA,” “A,” “P,” and “I” are used so a user can select the appropriate tidal volume size for the patient. An adult patient generally requires about 500 mL to about 750 mL of a volume of air, a pediatric patient generally requires about 150 mL to about 500 mL of a volume of air, and an infant patient generally requires about 30 mL to about 150 mL of a volume of air.

In order for a user to change the setting of the control dial 2012, the user must press down on the control dial 2012 and simultaneously rotate the control dial 2012 to adjust it to a desired setting. This safety feature prevents a user from accidentally turning the control dial 2012 to an inappropriate volume for the patient. In alternative embodiments, other safety mechanisms are contemplated, such as the use of a latch, or requiring the user to pull upward on the control dial before rotating, or another locking mechanism to prevent an inadvertent adjustment of the tidal volume.

The control dial 2012 includes at least one hollow portion that mates with a tab (not shown) of the first side panel 2002 a and another tab on the second side panel 2002 b to restrict the width at which the first and second side panels 2002 a, 2002 b open By doing so, when a user then compresses the expandable bag 2004 from this restricted width to a fully closed position, the volume of air delivered will be consistent and known within a small degree of variance. In an alternative embodiment, the control dial 2012 can permit the first and second side panels 2002 a and 2002 b to open fully while instead restricting how much the first and second side panels 2002 a, 2002 b close. The mechanism of control of the control dial 2012 is described in more detail below.

As shown in the figures, the control dial 2012 is located on a top portion of the valve housing member 2001. However, in other embodiments, the control dial 2012 may be located on a vertical side panel or other location of the valve housing member 2001.

In addition to controlling tidal volume, the control dial 2012 can also adjust a length of a spring of an internal PIP valve (shown in more detail at FIGS. 34-35). Adjustment of this spring makes it possible to apply a variable amount of downward pressure on the upper aspect of the PIP valve (not shown). When the PIP valve is fully restricted, it will not allow venting of excess pressure (simulating the infinite peak pressure valve that is sometimes needed for large adults). Thus an adjustment of PIP can modify the pressure at which excess pressure is vented from inside the valve housing member 2001 to the periphery.

As the control dial 2012 is rotated to a smaller patient setting, the control dial 2012 will adjust the length of a pop-off spring mechanism and allow the PIP valve to exhaust at lower pressures (a multiplicity depending on chosen settings). In an embodiment, the PIP values are infinite for a large adult, meaning there is no pressure release, 60 cm H₂O for a small adult, and 40 cm H₂O for a child or infant; however other values for relief pressures or sizes or grouping of patients are possible. The control dial 2012 allows for simultaneous adjustment of both tidal volume and PIP to a setting that is desired and appropriate for a given size of patient. In an alternative embodiment the adjustment of tidal volume and PIP may be decoupled.

The PEEP dial 2010 controls an ability of the two-way valve (not shown) to move vertically within the valve housing member 2001. When the PEEP dial 2010 is turned, it changes the pressure required for the patient to exhale. The PEEP dial 2010 can have different values such as from 0 to 20 cm H₂O in slidable increments that may be selectable on the PEEP dial 2010. Alternatively, the PEEP dial 2010 may be adjustable in discrete increments, such as increments of 5 cm H₂O or less.

The port 2008 may be used for a plurality of connections, including for example a medication injection device and end-tidal CO₂ detector. The port 2008 is located between the two-way valve and the mask connection member 2006. This allows for monitoring of CO₂ release from the patient during resuscitation or for the administration of medication directly to a patient's airway, without having to go through one of the valves of the valve housing member 2001.

The valve housing member 2001 is made from a rigid material, and in combination with a rigidity of the first side panel 2002 a and the second side panel 2002 b allows a user to hold the expandable bag device 2000 in one hand. A user is able to compress the expandable bag 2004 with one hand, while maintaining a seal of a mask on a patient's face with the same hand. The stiffness of the valve housing member 2001 and the first and second side panels 2002 a, 2002 b allows for single-handed use of the expandable bag device 2000.

FIG. 22 illustrates an alternative view of the expandable bag device 2000. The expandable bag 2004 is attached to the valve housing member 2001 via a bag connection member 2030 that allows air to flow from the expandable bag 2004 through the valve housing member 2001 and to the patient. The valve housing member 2001 is connected to the first and second side panels 2002 a, 2002 b.

The expandable bag device 2000 is designed so the compression of the expandable bag 2004 by the first and second side panels 2002 a, 2002 b, occurs along a plane that is parallel to the plane of a mask on a patient. Still further, the plane that the expandable bag 2004 compresses along is normal or perpendicular to the mask connection member 2006. In other words, in an expanded configuration, the expandable bag 2004 is larger at an end opposite the valve housing member 2001 than an end adjacent the valve housing member 2001.

Also shown is a PIP override tab 2020. The PIP override tab 2020 has two configurations. In a first configuration, the PIP override tab 2020 is in an override state, where no air is allowed to vent through the PIP valve, simulating an infinite PIP value. In a second configuration, when the PIP override tab 2020 is rotated such as 90° or 180°, the PIP override tab 2020 is not in an override state, where air is allowed to vent through the pressure relief opening 2013. The side panel 2002 b is shaped so as to hang slightly over the PIP override tab 2020 when the expandable bag 2004 is in an expanded state. In this embodiment, a user must first fully compress the bag in order to rotate the PIP override tab 2020 into a locked or unlocked position. This serves as a safety mechanism to prevent unintentional manipulation of the PIP override tab 2020.

FIG. 23 illustrates an example embodiment of the valve housing member 2001. The valve housing member 2001 includes the control dial 2012 at a first end, such as the top of the valve housing member 2001 when oriented on a patient in use, a mask connection member 2006 at a bottom end, and the PIP override tab 2020, a manometer port (not shown), the PEEP dial 2010, and the medication port or end-tidal CO₂ connection port 2008 located therebetween.

A manometer port (not shown) can be used to indicate the internal pressure levels of the expandable bag device 2000. In this embodiment the manometer port 2022 extends from the middle portion of the valve housing member 2001, however in other embodiments, the manometer port 2022 may extend from any other portion of the valve housing member 2001 or the bag connection member 2030.

The control dial 2012 surrounds an internal mechanism (not shown) that is capable of simultaneously controlling tidal volume and PIP. The internal mechanism of the control dial 2012 is shown in more detail at FIGS. 30, 32, and 34. The control dial 2012 includes settings identified by indicia to indicate which type of patient the expandable bag device 2000 is being used for. For example, “I” indicates infant use, “P” indicates pediatric use, and “A” indicates adult use. In an embodiment, the control dial 2012 may include additional settings, such as a large adult. The control dial 2012 provides for different tidal volumes and PIP within a given patient size class.

As shown in FIG. 23, the expandable bag 2004 is in an expanded configuration. An end of the expandable bag 2004 located away from the valve housing member 2001 has a width that is greater than a width of the expandable bag 2004 located near the valve housing member 2001.

The mask connection member 2006 extends from a second end of the valve housing member 2001 and is capable of connecting to a mask or other patient interfacing device, such as an endotracheal tube or laryngeal mask airway.

FIG. 24 illustrates a top view of the expandable bag device 2000 in an expanded configuration. As shown, the expandable bag 2004 has a generally triangular-shape when in the expanded configuration. The bag could assume other shapes such as spherical, ovoid, square, rectangular, or another polygonal shape. An end 2154 of the expandable bag 2004 opposite the valve housing member 2001 expands more than an end 2156 adjacent the valve housing member 2001.

A bag connection member 2030 is shown, which provides fluid communication between the expandable bag 2004 and the valve housing member 2001 to provide air to a patient. The bag connection member 2030 can also include a valve 2031 that prevents back flow of air from the valve housing member 2001 to the expandable bag 2004.

The valve housing member 2001 may also include a light 2152. To aid the user in preventing hyperventilation, or more specifically from inducing hyperventilation, the valve housing member 2001 includes a battery-powered, blinking light 2152. The light 2152 works in conjunction with the control dial 2012, blinking at a cadence specific to the tidal volume and PIP chosen on the control (infant, pediatric, adult, large adult) to indicate to the user the rate that is appropriate to deliver air to the patient. Additionally, the duration of the light blink indicates the time that it should take for the user to deliver air to the patient.

The light 2152 may blink at different speeds for different sizes of patients. For example, the light 2152 may blink every 1-2 seconds for an infant, 2-3 seconds for an infant or pediatric patient, and 5-6 seconds for an adult. However, other time periods are contemplated. The blinking light indicates to a user how often to compress the expandable bag 2004.

The light 2152 can be attached to the control dial 2012 via a conductive band that receives an input depending on what size of patient is selected on the control dial 2012. The light 2152 can determine the cadence at which the light 2152 blinks to display the appropriate timing for the user to squeeze the bag and give air to the patient. The light 2152 may also blink for a duration of time, such as 1 second, which corresponds to how long a user should take to fully compress the expandable bag 2004.

In an embodiment, the light 2152 can blink in a first color when the expandable bag device 2000 is being used properly by the user. When a user is not using the expandable bag device 2000 properly, the light 2152 can blink in a different color. For example, when the expandable bag 2004 is being compressed at a correct speed and correct duration, the light 2152 blinks with a green color. If the expandable bag 2004 is being compressed too quickly or too slow, the light 2152 may blink a red color.

The light 2152 may also be associated with a sound, such as an alarm or metronome. If the expandable bag 2004 is being compressed too quickly or too slow, in addition to or instead of a red colored blinking light, an alarm may sound. Still further, only a sound may be utilized to indicate the correct cadence, rate, compression time, or signal errors or provide other feedback to the user.

The light 2152 may be an LED or other type of light powered by a battery, such as a rechargeable battery or a non-rechargeable battery, or powered by a mechanical charging system utilizing the compression of the expandable bag 2004 to power the light 2152.

FIG. 25 illustrates an alternative side view of the expandable bag device 2000. As discussed above, the expandable bag device 2000 includes an expandable bag 2004 connected to a valve housing member 2001. The expandable bag device 2000 is shown in a compressed embodiment, where the expandable bag device 2000 takes up minimal space.

The first side panel 2002 a also includes an air intake mechanism 2040. The air intake mechanism 2040 includes an oxygen exhaust valve 2044, an ambient air inlet valve 2046, and an oxygen inlet port 2042. The air intake mechanism 2040 allows air to flow into the expandable bag 2004.

The air intake mechanism 2040 includes the oxygen inlet port 2042, the oxygen exhaust valve 2044, an air inlet valve 2046, an expandable bag inlet valve (not shown), and a hyperventilation override slide (not shown).

In use, supplementary oxygen may be provided to the expandable bag 2004 via the oxygen inlet port 2042. The air intake mechanism 2040 includes a check valve system that allows the user to add supplementary oxygen to the ambient air within the expandable bag 2004 at a controlled rate by only letting a specified volume of oxygen into the expandable bag 2004 over time, while excess oxygen is exhausted through an oxygen exhaust valve 2044 to the periphery. This system regulates the rate at which oxygen and ambient air are allowed into the expandable bag regardless of the rate at which oxygen is set to flow into the oxygen inlet port 2042 such as at 10 L/min, 15 L/min, etc.

In a further embodiment, an auditory indicator may provide a first sound while the expandable bag 2004 is inflating, and a second sound when the expandable bag has reached maximum volume.

FIG. 26 shows another side view of the expandable bag device 2000. The expandable bag device 2000 is shown in a compressed embodiment, where the expandable bag device 2000 takes up minimal space. Further, the second side panel 2002 b does not include an air intake mechanism 2040. However, in other embodiments, the second side panel 2002 b may include the air intake mechanism 2040 or a duplicate or alternative air intake mechanism.

FIG. 27 illustrates a bottom view of the expandable bag device 2000 in an expanded configuration. The valve housing member 2001 is connected to the expandable bag 2004 via the bag connection member 2030, which includes a one-way valve (not shown) that allows air to flow from the expandable bag 2004 to the valve housing member 2001. Also shown is a mask connection lumen 2007 within the mask connection member 2006, which is in fluid communication with the expandable bag 2004 via the bag connection member 2030 to deliver air to a patient through a mask or other patient interface device (not shown).

FIG. 28 shows another view of the expandable bag device 2000. As described above, the expandable bag device 2000 includes the valve housing member 2001 in fluid communication with the expandable bag 2004. The air intake mechanism 2040 is located on a first side panel 2002 a.

FIG. 29 illustrates an isolated view of the valve housing member 2001. The valve housing member 2001 is shown in a use orientation. A mask connection member 2006 is located at a bottom end of the valve housing member 2001, and the control dial 2012 is located at a top end of the valve housing member 2001.

A body 2032 of the valve housing member 2001 is located below the control dial 2012, and houses at least the light (not shown) and the PIP override tab 2020. Below the body 2032 is the PEEP dial 2010. A port 2008 is located near the mask connection member 2006, although its exact location may be anywhere along the path of the air coming from the expandable bag (not shown) and below the two-way valve. In an embodiment, the port 2008 may be a medication port, which allows direct administration to a patient without having to administer the medication through any of the valves.

The PIP override tab 2020 has a tab 2606 that is pointing along a plane perpendicular to the expandable bag (not shown). The tab 2606 can be rotated by a user to point along a plane that extends perpendicular to the valve housing member 2001, which creates an infinite PIP valve.

FIG. 30 illustrates a cutaway view of the valve housing member 2001. In particular, the cutaway view of the valve housing member 2001 illustrates a two-way valve 2124 located centrally in the mask connection lumen 2007. The two-way valve 2124 functions to deliver air from the expandable bag (not shown) to the patient, while also providing a PEEP functionality.

In an embodiment, the two-way valve 2124 is a duckbilled valve that includes two flaps that meet each other in a center of the mask connection lumen 2007 and pointing in a direction towards a mask (not shown). In another embodiment, the two-way valve 2124 is an umbrella valve that is secured within the mask connection lumen 2007.

The desired PEEP value is controlled by the PEEP dial 2010 and can be adjusted to a predetermined PEEP value as desired by the user. The two-way valve 2124 in combination with a lifting piece 2125 creates PEEP to maintain predetermined pressure in the lungs of the patient. The two-way valve 2124 allows air from the expandable bag 2004 to be provided to the patient and forces exhaled air to lift the two-way valve 2124 off of the lifting piece 2125.

The PEEP dial 2010 controls the PEEP value via an internal thread 2120. For example, rotating the PEEP dial 2010 increases or decreases the tension of a lifting piece 2125 against the two-way valve 2124, which effectively changes the force required for a patient to exhale air through the PEEP valve. No tension between the lifting piece 2125 results in no generation of PEEP. Low tension at the connection of the lifting piece 2125 and the two-way valve 2124 results in a low PEEP value, while higher tension between the lifting piece 2125 and the two-way valve 2124 results in a higher PEEP value. The PEEP valve and mechanism is shown in more detail at FIG. 35.

At higher breath pressures coming from the patient, the pressure will surmount the PEEP value, but as the breath pressures decrease, the two-way valve 2124 returns to its resting position against the lifting piece 2125, which forces the pressure to be maintained within the patient's lungs. This allows for easier administration of subsequent breaths into the patient, thus more efficient and effective bagging.

Also shown is the PIP control mechanism 2100, which is also controlled by the control dial 2012. By adjusting the control dial 2012, the pressure at which air vents to the periphery is changed and the tidal volume provided by the expandable bag 2004 is changed. The adjustment of the control dial 2012 modifies the pressure at which excess pressure is vented from inside the expandable bag device 2000 to the periphery.

When the PIP value is fully restricted, it will not allow venting of excess pressure (simulating the infinite peak pressure valve that is sometimes needed for certain clinical scenarios). As the control dial 2012 is rotated and then released to the various patient settings, the height of the control dial 2012 will be restricted by the use of inverted wells 2112, 2114, 2116, 2118. The relative height of these inverted wells 2112, 2114, 2116, 2118 will adjust the length of the pop-off spring 2119 and allow the pop-off valve to exhaust at a variety of pressures. Predetermined PIP values are infinite for a large adult, 60 cm H₂O for a small adult, and 40 cm H₂O for a child or infant; however, other values are possible.

The PIP control mechanism 2100 includes at least four settings, or inverted wells 2112, 2114, 2116, 2118, which correspond to the predetermined PIP values. When the control dial 2012 is turned, a desired setting is selected. In an embodiment, a first inverted well 2112 has a short length, and corresponds to a PIP value of 60 cm of H₂O for adults. A second inverted well 2114 has a medium length, and corresponds to a PIP value of 40 cm of H₂O for pediatric patients. A third inverted well 2116 has a long length, and corresponds to a PIP value of 40 cm of H₂O for infants. A fourth inverted well 2118 has a shortest length and corresponds to an infinite PIP value.

The PIP control mechanism 2100 includes four inverted wells, where each inverted well corresponds to the inverted wells 2112, 2114, 2116, 2118. The control dial 2012 also includes a spring which requires a predetermined amount of force to turn the control dial 2012. In an alternative embodiment the same mechanism could be achieved using right-side-up wells. This would particularly apply in an embodiment wherein the control dial 2012 is pulled upward and rotated to adjust instead of being depressed and rotated to adjust.

The two-way valve 2124 also provides additional functionally, by restricting a flow of fluids back into the valve housing member 2001. For example, if a patient vomits, the two-way valve 2124 prevents fluid from entering the valve housing member 2001 and directs it out of the valve housing member 2001, similar to the direction air flows as a result of the PEEP setting.

FIG. 31 illustrates a view of the valve housing member 2001 highlighting the PIP override tab 2020. When a user activates the PIP override tab 2020, the PIP valve will not activate and thus at no pressure will air vent through the pressure relief opening. The PIP override tab 2020 extends out from a center of the valve housing member 2001. In a first embodiment, when the PIP override tab 2020 is in an override state, the tab 2606 is pointed towards the expandable bag 2004. In a second embodiment, when the PIP override tab 2020 is not in an override state, the tab 2606 is pointed in a direction opposite the expandable bag 2004, such as in line with the mask connection member 2006. However, the direction of the tab 2606 corresponding to the first or second embodiment should not be seen as limiting, as other directions are possible.

The user is able to rotate the PIP override tab 2020 as desired, for example from the first embodiment to the second embodiment, and back, if needed. The PIP override tab 2020 has a tab 2606, and an extension portion 2602 connecting to a concentric spring mechanism 2604. An end 2608 of the extension portion 2602 has a semicircular or other shape that mates with a corresponding shape of the PIP valve (not shown).

In an embodiment, the PIP override tab 2020 and semicircular mating portion do not form concentric semicircles and do not interact allowing air to vent from the top of the device at the desired pressure. When the PIP override tab 2020 is in the override state, a cutout in the extension portion 2602 and the semicircle portion of the PIP override tab 2020 interact and become concentric. The semicircular mating portion is now locked in position, closing off the pressure relief opening at the top of the valve housing member 2001, and not allowing air to vent out (or setting the PIP valve to an infinite pressure). In an embodiment the PIP override tab may be external to the valve housing member 2001 and function by being lifted and applying downward force on the upper aspect of the control dial 2012 to compress the spring over the rod 2602 and prevent venting of excess pressures.

FIG. 32 illustrates a cutaway view of the valve housing member 2001 with a different style of two-way valve 2124. The valve housing member 2001 also includes the control dial 2012, which controls the tidal volume of the expandable bag (not shown) and the PIP inverted wells 2112, 2114, 2116, 2118. Further shown is the internal threads 2120 which dictates the amount that the two-way valve 2124 is allowed to move, and provides PEEP.

FIG. 33 illustrates the valve housing member 2001 and indicating a direction that air flows. Air flow follows the path A from the inflatable bag (not shown) through the bag connection member 2030, into the valve housing member 2001, through the mask connection member 2006, and eventually to the patient through a mask (not shown).

Upon expiration, the patient exhales, and the air follows path B. The exhaled air moves back through the mask connection member 2006 and out through an opening created by moving the two-way valve within the valve housing member 2001.

FIG. 34 shows the location of the PIP override tab 2020, when viewed through the valve housing member 2001. As described above, the PIP override tab 2020 has a tab (not shown), a rod (not shown) connecting to a concentric spring mechanism (not shown). An end 2608 of the rod has a circular shape that mates with a corresponding shape of the PIP mechanism (not shown).

FIG. 35 illustrates an exploded view of the valve housing member 2001. The control dial 2012 is located at an end of the valve housing member 2001; however, the exact location of the control dial 2012 is variable. As the control dial 2012 rotates it communicates with one of the inverted wells 2112, 2114, 2116, 2118, which correspond to a predetermined PIP value. A spring (not shown) maintains the control dial 2012 in the correct position, such that to turn the control dial 2012 the strength of the spring must be overcome.

The control dial 2012 also controls the tidal volume provided by the expandable bag. The control dial 2012 includes a tidal volume controller that communicates with the first side panel 2002 a and the second side panel 2002 b to control the width at which the panels are allowed to expand. In a first configuration, a tidal volume controller has an octagonal shape (four pairs of settings) that restrict the width that the first side panel 2002 a and the second side panel 2002 b are allowed to expand. A hinge located with the expandable bag 2004 forces the first side panel 2002 a and the second side panel 2002 b to open, and the tidal volume controller determines how much the first side panel 2002 a and the second side panel 202 b are allowed to open.

In an alternative configuration, the tidal volume controller restricts the width that the first side panel 2002 a and the second side panel 2002 b are allowed to close relative to each other. The hinge located with the expandable bag 204 forces the first side panel 2002 a and the second side panel 2002 b to open, and the tidal volume controller determines how much the first side panel 2002 a and the second side panel 2002 b are allowed to close when being compressed by a user.

The bag connection member 2030 includes a valve 2031 that only allows air to from the expandable bag to the valve housing member 2001. The valve 2031 prevents any backflow of air from the valve housing member 2001 into the expandable bag. In an embodiment, the valve 2031 is an umbrella valve.

The two-way valve 2124 allows air to flow to the patient from the valve housing member 2001 in a first direction and forces exhaled air from the patient to exhaust into the periphery. As shown, the PEEP dial 2010 is located within an internal thread 2120, and the extent to which the lifting piece 2125 is allowed to move vertically within the valve housing member 2001 is dictated by the location of the PEEP dial 2010 along the internal thread 2120. In an embodiment as shown, the two-way valve 2124 is a duck-billed valve, and in alternative embodiments, the two-way valve 2124 may be an umbrella valve.

The PEEP dial 2010 surrounds the location of the two-way valve 2124. The PEEP dial 2010 is capable of being turned by a user to a desired PEEP value, which corresponds to amount of tension between the lifting piece 2125 and the two-way valve 2124. The force required by exhaled air to move the two-way valve 2124 off of the lifting piece 2125 corresponds to the PEEP value selected.

The two-way valve 2124 also prevents backflow of fluids into the valve housing member 2001. The two-way valve 2124 prevents fluid from entering the valve housing member 2001 and directs fluid out of the valve housing member 2001, similar to the direction air flows as a result of the PEEP setting

FIG. 36 shows the expandable bag device 2000 with the expandable bag 2004 in an expanded configuration. The first side panel 2002 a includes the air intake mechanism 2040. The air intake mechanism 2040 includes an oxygen inlet port 2042, an oxygen exhaust valve 2044, an air inlet valve 2046, a bellows inlet valve (not shown), and a hyperventilation override slide 2048.

The oxygen inlet port 2042 is capable of connecting to an oxygen source, to provide oxygen to the expandable bag. The oxygen exhaust valve 2044 vents excess oxygen from the air intake mechanism 2040 to the periphery when the pressure within the air intake mechanism 2040 is too high. The air inlet valve 2046 allows ambient air to enter the air intake mechanism 2040, and ultimately into the expandable bag 2004 via plurality of apertures (not shown).

FIG. 37 illustrates a cutout side view of the air intake mechanism 2040. An inlet pressure valve 2050 allows external air to enter the inflatable bag from the interior of the air intake mechanism 2040. The inlet pressure valve 2050 is an umbrella valve. The air may be external ambient air or a combination of ambient air and oxygen. Ambient air enters the air intake mechanism 2040 through an air inlet valve 2046, and oxygen enters the air intake mechanism 2040 through an oxygen inlet port (not shown). The air inlet valve 2046 is also an umbrella valve.

The air intake mechanism 2040 includes the oxygen inlet port (not shown) to control the proportion of oxygen entering the inflatable bag. In use, oxygen flows into the air intake mechanism 2040 at a rate specified on the oxygen tank, which is usually between 10-15 L/min. The pressure from the oxygen inlet port 2042, combined with the atmospheric pressure, creates a pressure differential between the air intake mechanism 2040 and the expandable bag 2004. Oxygenated air will fill the expandable bag 2004 if the pressure is above that of the inlet pressure valve 2050 and less than the oxygen exhaust valve 2044.

In an embodiment, the flow rate from the oxygen tank is high (for example 10-15 L/min) and the cracking pressure for the oxygen exhaust valve 2044 is kept low to limit the pressure differential created by oxygen flowing into the air intake mechanism 2040.

The air intake mechanism 2040 allows the expandable bag 2004 to fill with oxygen at a consistent flow rate no matter the flow rate from the oxygen tank. The air intake mechanism 2040 also provides for a consistent inflation rate for the expandable bag 2004, no matter the source of the air (straight ambient air, pure oxygen, or a mixture of ambient air and oxygen).

In a further embodiment, the air intake mechanism 2040 includes the override slide 2048. The override slide 2048 may be a sliding wheel, a cinch threading mechanism, two sliding plates, or a push button mechanism. The override slide 2048 may be used to allow for hyperventilation by controlling the size of the plurality of apertures (not shown) that allow air to enter the expandable bag 2004. In an embodiment, the override slide 2048 aligns an aperture on side panel 2002 a with a corresponding aperture on the override slide 2048. This slide may be a barrel valve or other mechanism which allows for a plurality of aperture sizes and thus a plurality of inflation rates of the expandable bag 2004 between a fully restricted (slow) rate and a fully open (fast) rate.

FIG. 38 illustrates a top view of the expandable bag device 2000 in a compressed configuration. The first side panel 2002 a and the second side panel 2002 b are generally parallel to each other, with the expandable bag 2004 located there between.

FIG. 39 illustrates a partial cutaway view of the valve housing member 2001 highlighting the bag connection member 2030. Air flow from the expandable bag 2004 through a valve 2131 in the bag connection member 2030 and into the valve housing member 2001. The valve 2131 prevents air from flowing from the valve housing member 2001 back into the expandable bag 2004.

FIG. 40 illustrates an exploded view of the air intake mechanism 2040 and the expandable bag 2004. Ambient air enters the air intake mechanism 2040 through an air inlet valve 2046, and oxygen enters the air intake mechanism 2040 through an oxygen inlet port 2042. The ambient air and the oxygen mix within the air intake mechanism 2040 and enter the expandable bag 2004 via a plurality of apertures 2158 a, 2158 b, the size and number of which are opened to the expandable bag 2004 are controlled by the override slide 2048.

The air intake mechanism 2040 includes the oxygen inlet port 2042 which provides the flow of oxygen with the atmospheric air through the air intake mechanism 2040. The oxygen inlet port 2042 only allows oxygen to flow into the air intake mechanism 2040.

The oxygen exhaust valve 2044 vents excess oxygen into the atmosphere, so it does not enter the expandable bag 2004 and allows for consistent filling times of the expandable bag 2004 regardless of oxygen flow rates from the oxygen source into the air intake mechanism. The override slide 2048 controls an aperture covering mechanism 2052 that determines either the size or the number of apertures 2158 that air is allowed to enter the expandable bag 2004 from the air intake mechanism 2040.

FIG. 41 illustrates a cutaway bottom view of the valve connection member 2001 highlighting the control dial 2012. The control dial 2012 extends around an exterior of the valve housing member 2001. The control dial 2012 comprises the tidal volume controller that has an octagonal shape (four pairs of settings 2202 a, 2202 b, 2204 a, 2204 b, 2206 a, 2206 b, 2208 a, 2208 b) that restrict the width that the first side panel 2002 a and the second side panel 2002 b are allowed to expand

FIG. 42 illustrates a view of the expandable bag in an expanded configuration. As shown, an end 2154 of the expandable bag 2004 opposite the valve housing member 2001 expands more than an end 2156 adjacent the valve housing member 2001. In the embodiment shown, the air intake mechanism 2040 is located near the end 2154 of the side panel; however the air intake mechanism 2040 may be located in other places in fluid communication with the expandable bag 2004.

FIGS. 43-45 illustrates an embodiment of the air intake mechanism 2040 with the slide in various positions. FIG. 43 illustrates an embodiment of the air intake mechanism with the slide in a first position. FIG. 44 illustrates an embodiment of the air intake mechanism with the slide in a second position. FIG. 45 illustrates an embodiment of the air intake mechanism with the slide in a third position.

Each position of the override slide 2048 corresponds to a different flow rate from the air intake mechanism 2040 to the expandable bag 2004. The first position of the override slide 2048 allows for air to flow into the expandable bag 2004 at a first rate, the second position of the override slide 2048 allows for air to flow into the expandable bag 2004 at a second rate, and the third position of the override slide 2048 allows for air to flow into the expandable bag 2004 at a third rate.

Embodiments of the present invention, for example, are described above with reference to block diagrams and/or operational illustrations of methods, systems, and computer program products according to embodiments of the invention. The functions/acts noted in the blocks may occur out of the order as shown in any flowchart. For example, two blocks shown in succession may in fact be executed substantially concurrently or the blocks may sometimes be executed in the reverse order, depending upon the functionality/acts involved.

The description and illustration of one or more embodiments provided in this application are not intended to limit or restrict the scope of the invention as claimed in any way. The embodiments, examples, and details provided in this application are considered sufficient to convey possession and enable others to make and use the best mode of claimed invention. The claimed invention should not be construed as being limited to any embodiment, example, or detail provided in this application. Regardless of whether shown and described in combination or separately, the various features (both structural and methodological) are intended to be selectively included or omitted to produce an embodiment with a particular set of features. Having been provided with the description and illustration of the present application, one skilled in the art may envision variations, modifications, and alternate embodiments falling within the spirit of the broader aspects of the claimed invention and the general inventive concept embodied in this application that do not depart from the broader scope. 

1. A respiratory device for providing respiratory support to a patient, the respiratory device comprising: an expandable bag comprising an air intake valve, the expandable bag having an adjustable predetermined tidal volume and a hinge, the hinge configured to maintain the expandable bag in a predetermined tidal volume in an uncompressed configuration; a rigid valve housing portion in fluid communication with the expandable bag, the valve housing portion comprising: an adjustable peak inspiratory pressure (PIP) mechanism; an adjustable dial configured to adjust the tidal volume of the expandable bag and a value of the PIP mechanism; a two-way valve configured to allow air to move from the expandable bag in a first direction through a first portion and directs air in an opposing direction through a second portion to create positive end-expiratory pressure (PEEP); a PEEP controller comprising a PEEP dial configured to select a predetermined PEEP value provided by the two-way valve; and wherein the valve housing portion is capable of connecting to a patient breathing interface.
 2. The respiratory device of claim 1, wherein the two-way valve is selected from a duckbilled valve and an umbrella valve.
 3. The respiratory device of claim 1, wherein the PEEP controller comprises the PEEP dial, a two-way valve, and a lifting piece, wherein movement of the PEEP dial lifts the lifting piece relative to the two-way valve to adjust a tension between the lifting piece and the two-way valve, and wherein when the lifting piece is in a lifted configuration, a variable seal is formed by the lifting piece and the two-way valve.
 4. The respiratory device of claim 3, wherein the lifting piece forms a tight junction against an underside of the two-way valve to prevent the flow of liquid fluids from the patient into an opposing side of the two-way valve.
 5. The respiratory device of claim 1, wherein the adjustable dial has a plurality of predetermined settings to simultaneously select the value of the PIP mechanism and the tidal volume of the expandable bag that correspond to a size of the patient.
 6. The respiratory device of claim 5, wherein the adjustable dial comprises a plurality of inverted wells, wherein each well corresponds to the predetermined setting of the value of the PIP mechanism and the tidal volume.
 7. The respiratory device of claim 1, wherein the valve housing portion comprises a first end adjacent the patient breathing interface and an opposing second end, and wherein the adjustable dial is at a location selected from the opposing second end of the valve housing portion and between the first end and the opposing second end of the valve housing portion.
 8. The respiratory device of claim 1, wherein the rigid valve housing portion comprises an inlet connected to the expandable bag, the inlet having a central axis, and an outlet configured to be connected to the patient breathing interface, and the outlet having a central axis perpendicular to the central axis of the inlet.
 9. The respiratory device of claim 8, wherein the expandable bag comprises a first end connected to the inlet of the rigid valve housing portion, and wherein a second end of the expandable bag expands a greater amount than the first end of the expandable bag when viewed along a plane defined by the central axis of the inlet and perpendicular to the central axis of the outlet.
 10. The respiratory device of claim 1, further comprising an intake mechanism in fluid communication with the expandable bag, the intake mechanism comprising: a plurality of adjustable apertures in fluid communication with the expandable bag; an ambient air intake valve; an oxygen intake valve; and an exhaust valve.
 11. The respiratory device of claim 10, wherein the intake mechanism further comprises an override switch, configured to modify a size of the adjustable apertures to control a speed of entry of gasses into the expandable bag.
 12. The respiratory device of claim 1, wherein the rigid valve housing portion further comprises a PIP override mechanism, wherein in an engaged configuration, the PIP override mechanism prevents a lifting of the PIP mechanism and provides an infinite value of PIP.
 13. The respiratory device of claim 1, wherein the rigid valve housing portion further comprises a light, wherein the light is configured to blink at an adjustable predetermined interval and for a predetermined duration of time corresponding to a rate and a speed at which the expandable bag is to be compressed by a user, and wherein the rate and speed corresponds to the value of the adjustable dial.
 14. The respiratory device of claim 1, wherein the rigid valve housing portion further comprises a light, wherein the light is configured to provide feedback to the user based on user compliance.
 15. The respiratory device of claim 1, wherein the rigid valve housing portion further comprises a manometer port.
 16. The respiratory device of claim 1, wherein the rigid valve housing portion further comprises a medication and an end-tidal CO₂ port located at an end of the rigid valve housing portion between a location of the two-way valve and the patient breathing interface.
 17. The respiratory device of claim 1, further comprising a first side panel and a second side panel enclosing the expandable bag, and wherein the adjustable dial comprises a tidal volume controller configured to control a width at which the first side panel and the second side panel expand or contract from each other to control the tidal volume of the expandable bag.
 18. The respiratory device of claim 1, wherein the adjustable dial is configured to simultaneously adjust the tidal volume of the expandable bag and a value of the PIP mechanism.
 19. A method of providing respiratory support to a patient, the method comprising: providing the respiratory device of claim 1; selecting a predetermined value of the tidal volume and the value of the PIP mechanism on the adjustable dial; selecting a PEEP value on the PEEP controller; and wherein the respiratory device is configured for single-handed use by a user.
 20. A respiratory device for providing respiratory support to a patient, the respiratory device comprising: an expandable bag comprising an air intake valve, the expandable bag having an adjustable predetermined tidal volume and a hinge, the hinge configured to maintain the expandable bag in a predetermined tidal volume in an uncompressed configuration; an adjustable intake mechanism comprising at least one adjustable aperture in fluid communication with the expandable bag, the intake mechanism comprising an ambient air intake valve, an oxygen intake valve, an exhaust valve, and a switch configured to modify a size of the at least one adjustable aperture to control a speed of entry of gasses into the expandable bag; a rigid valve housing portion in fluid communication with the expandable bag, the valve housing portion comprising: a peak inspiratory pressure (PIP) mechanism; an adjustable dial configured to adjust both the tidal volume of the expandable bag and a value of the PIP mechanism; a two-way valve configured to allow air to move from the expandable bag in a first direction and directs air through a positive end-expiratory pressure (PEEP) valve in an opposing direction; a PEEP controller comprising a PEEP dial and a lifting piece, wherein movement of the PEEP dial lifts the lifting piece relative to the two-way valve to adjust a tension between the lifting piece and the two-way valve, to select a predetermined PEEP value provided by the two-way valve; and wherein the valve housing portion is capable of connecting to a patient breathing interface.
 21. The respiratory device of claim 19, wherein the rigid valve housing portion further comprises a PIP override mechanism, wherein in an engaged configuration, the PIP override mechanism provides an infinite value of the PIP mechanism.
 22. The respiratory device of claim 19, wherein the two-way valve is selected from a duckbilled valve and an umbrella valve.
 23. A rigid valve housing portion for use in providing respiratory support to a patient, the valve housing portion comprising: a peak inspiratory pressure (PIP) mechanism; an adjustable dial configured to adjust both a tidal volume of an expandable bag and a value of the PIP mechanism; a two-way valve configured to allow air to move from the expandable bag in a first direction through a first portion and directs air in an opposing direction through a second portion to create positive end-expiratory pressure (PEEP); a PEEP controller comprising a PEEP dial configured to select a predetermined PEEP value provided by the two-way valve; and wherein the valve housing portion is capable of connecting to a patient breathing interface.
 24. The rigid valve housing portion of claim 23, wherein the PEEP controller comprises the PEEP dial and a lifting piece, wherein movement of the PEEP dial lifts the lifting piece relative to the two-way valve to adjust a tension between the lifting piece and the two-way valve, and wherein when the lifting piece is in a lifted configuration, a variable seal is formed by the lifting piece and the two-way valve.
 25. The rigid valve housing portion of claim 23, wherein the adjustable dial has a plurality of predetermined settings to simultaneously select the value of the PIP mechanism and the tidal volume of the expandable bag that correspond to a size of the patient.
 26. The rigid valve housing portion of claim 25, wherein the adjustable dial comprises a plurality of inverted wells, wherein each well corresponds to the predetermined setting of the value of the PIP mechanism and the tidal volume.
 27. The rigid valve housing portion of claim 23, wherein the valve housing portion comprises a first end adjacent the patient breathing interface and an opposing second end, and wherein the adjustable dial is at a location selected from the opposing second end of the valve housing portion and between the first end and the opposing second end of the valve housing portion.
 28. The rigid valve housing portion of claim 21, wherein the rigid valve housing portion further comprises a PIP override mechanism, wherein in an engaged configuration, the PIP override mechanism prevents a lifting of the PIP mechanism and provides an infinite value of PIP.
 29. The rigid valve housing portion of claim 23, wherein the rigid valve housing portion further comprises a light, wherein the light is configured to blink at an adjustable predetermined interval and for a predetermined duration of time corresponding to a rate and a speed at which the expandable bag is to be compressed by a user, and wherein the rate and speed corresponds to the value of the adjustable dial.
 30. The rigid valve housing portion of claim 23, wherein the rigid valve housing portion further comprises a light, wherein the light is configured to provide feedback to the user based on user compliance. 